About This Item
- Full text of this item is not available.
- Abstract PDFAbstract PDF(no subscription required)
Share This Item
The AAPG/Datapages Combined Publications Database
Houston Geological Society Bulletin
Abstract
Abstract: The Art and Science in the
Borehole
Image
Interpretation of Deepwater
Gravity
Flow Sediments
![Previous Hit](/data/images/arrow_left.gif)
![Next Hit](/data/images/arrow_right.gif)
![Previous Hit](/data/images/arrow_left.gif)
![Next Hit](/data/images/arrow_right.gif)
Shell
High-resolution borehole
images (BHIs) provide fine-scale
rock fabric data that may be critical to the understanding
of reservoir geology and production performance. However,
interpreting deepwater
gravity
-flow sedimentary systems based
on
borehole
images and dipmeter logs in widely spaced
subsurface penetrations is often considered “artistic”, particularly
when the log data and/or the geology are uncertain.
In order to improve the scientific interpretation and effectively include valid geology in the reservoir models, multiple BHI interpretation case studies have been conducted for various geological objectives. These include the sedimentary environments and reservoir architectures in the oil and gas fields in the Gulf of Mexico and the Arkoma basin, Oklahoma. The integrated petrophysical and sedimentary facies interpretation of the BHI and conventional logs were calibrated in the core wells, particularly in the Gulf of Mexico. This established the proper interpretation methodology and identified the BHI data limitations and interpretation pitfalls. This learning process is necessary to reduce the uncertainty in multi-well field studies without cores.
Some of the BHI data were independently interpreted by several BHI specialists of different backgrounds before the core calibration work. These comparisons demonstrate how the degree of art and science varies in the BHI interpretation with the interpreter more than with the data or the actual geology. Although it may be difficult to scientifically prove an interpretation correct or incorrect even with a core calibration, a good interpretation should not be judged only by its geological story but also by how transparent and adequate it is for the end-users to understand the basis of the story. Over-interpretation of the BHI data and lack of petrophysical integration are the two most common causes for poor geological interpretations.
Figure 1. Different deformation and remobilization structures in the
deepwater gravity
flow sediments in the Red Oak Field, Oklahoma.
a) BHI interpretation in Well #6 (of the 12 wells studied) shows that
the Red Oak sandstones overlie pelagic shale and slumped
mudstones (mass transport). The dip results illustrate slump structures
of different scales in the mudstones, but the Red Oak channel
sandstones and the debrites (CMT) are not deformed. The facies
symbols between the log and depth tracks are illustrated by the
facies legend in Figure 2. Figures b to g are examples taken from
different intervals in the same well. They are: b) post-depositional
fracture and fault showing truncation of hanging wall and footwall
beds; c) low-angle surfaces truncating the high-angle tilted thinbedded
sediments both above and below the surfaces, interpreted as
slides; d) slumped thin-bed sediments showing an over-turned fold;
e) small-scale intra-bedded soft sediment deformation; f) nearvertical
sand flow penetrating the low-angle beds, possibly due to
water escape or sand injection; and g) sand breccias possibly resulted
from loading of in-situ sand beds into the mudstone.
Figure 2 The Red Oak channel complex in Well #1 (of the 12 wells studied) is characterized by a thin layer of channel-basal conglomerates, followed by massive clast-rich sandstones (Figure 3a) and scour-and-fill sandstones with inclined bedding (Figure 3b). Debrites and cogenetic turbidites are deposited in the middle of the channel fills (Figure 3c). The tracks are 1) GR with orange shade for sand; 2) classified facies (legend on the upper right) and measured depth in feet; 3) array induction resistivity logs (AIT) in ohmm (10 in to 90 in depth of investigation); 4) NPHI and RHOB logs; 5) static image with the darker colors presenting more conductive (muddy) lithology and lighter colors for more resistive; and 6) manually picked and classified dips (same in all other figures): inclined sand bedding dips in red, scour surfaces (yellow), shale/silt bedding and structural dip (green), deformed bedding (blue), computer-generated mean-square-dip (black), and fractures (flat “T”-shaped symbols). The black square brackets on the right side indicate the intervals with enlarged figures. The structural dip is almost constant at about 28ºSSW in the Red Oak interval. It is overlain by post-Red Oak muddy deposits with an upward-decreasing dip trend.
Figure 3a) The basal Red Oak channel fills of conglomerates and clast-rich conformable sandstones overlie the thin-bed levee facies. b) Stack of scour-and-fills with multiple inclined-bedding sets bounded by scour surfaces. The black scales on the right of figures 3a and 3b show the thickness variation of the massive sands and inclined-bedding sets in the scour-and-fill elements. c) A debrite layer within the Red Oak channel fills showing a muddy-upward profile and transition boundaries with the underlying and overlying co-genetic sandstones. d) Multiple thin muddy debrites and co-genetic sandstones interbedded with hemi-pelagic shales in a distal environment.